!!!! The Ag nanoparticle array can be considered Ag nanorods arranged in hexagonal pattern with an inter-nanorod gap (W). The rod diameter (D) is 25 nm and the rod length (L) is 100 nm. A series of curved hexahedral sub-domains and mesh sampling points therein are created. A plane EM wave impinges on the array vertically and the scattered radiation is collected around the cone at q = 45!. After the field on the top surface was obtained, the scattered radiation in far field was then calculated based on field equivalence principle. B.-Y. Lin et al., Opt. Express 17, 14211 (2009).
! The calculated far-field spectra follow the experimental data qualitatively: The resonance wavelength increases and the width is broadened as the interparticle gap decreases. B.-Y. Lin et al., Opt. Express 17, 14211 (2009).
! For all the different interparticle gaps, the far-field scattering is dominated by surface electric current density (J) which is generated by surface magnetic field, according to field equivalence principle.! In contrast, surface magnetic current density (M), generated by surface electric field, plays a minor role in far-field scattering. B.-Y. Lin et al., Opt. Express 17, 14211 (2009); S. R. Rengarajan and Y. Rahmat-Samii, IEEE Antennas Propagat. Mag. 42, 122 (2000).
! The surface electric field is localized at the gap region between adjacent Ag nanoparticles.! The surface magnetic field is delocalized over the whole surface and produces the corresponding J that acts as the dominant source of the far-field scattering.! The so-called hot spots created by the localized surface electric field has a minor role in producing far-field scattering. B.-Y. Lin et al., Opt. Express 17, 14211 (2009).
! Electric field resides within the gap and exhibits an evanescent character.! Magnetic field delocalizes over the surface and shows mainly a propagating character.! In surface-enhanced Raman scattering, the localized surface electric field interacts with the molecules residing in the gap region, producing a similar electric field distribution at a Ramanshifted wavelength. The resultant concurrent surface magnetic field then makes a major contribution to produce Raman scattering field in far distance. B.-Y. Lin et al., Opt. Express 17, 14211 (2009).
! Raman spectroscopy, providing molecular vibrational information, can become a powerful and useful method to identify molecular species if its scattering cross section can be enhanced many orders of magnitude.! Surface-enhanced Raman scattering (SERS) may serve as the solution.! Most of Raman enhancers have suffered two major drawbacks: low reproducibility and small dynamical range. Therefore, a lot of efforts have been made to control its enhancement mechanisms such that uniform high sensitivity can be achieved.! One key point is whether it is possible to control precisely the electromagnetic enhancement factor induced by plasmonic resonance.! Theoretical and experimental studies indicate that the precise control of gaps between nanostructures in the sub-10 nm regime, hot junctions, is likely to be critical for the fabrication of SERS-active substrates with uniformly high Raman enhancement factor.
! These substrates are commercially available. T.-T. Liu et al., PLoS ONE 4, e5470 (2009).
Staphylococcus aureus 13649 treated with vancomycin! Drastic change in SERS spectra was observed when treated with vancomycin. T.-T. Liu et al., PLoS ONE 4, e5470 (2009).
Inhibition of Cell Wall Synthesis (most common mechanism) Inhibition of Protein Synthesis (second largest class)! S. Aureus responds within 2 hrs to the antibiotics which inhibit cell-wall synthesis, while the response is delayed to longer than 8 hrs. for that which inhibit protein synthesis. T.-T. Liu et al., PLoS ONE 4, e5470 (2009).
! Scattering-type SNOM has been demonstrated to serve as a nanoprobe to investigate local optical properties and to probe local field distribution.! The uniform and highly reproducible SERS-active properties and the wide dynamical range facilitate the use of SERS for chemical and biological sensing applications with high sensitivity.! The electromagnetic interaction in arrays of Ag nanorods embedded in AAO has been investigated thoroughly by both experimental and theoretical methods.